This document discusses biogas technology and successful biogas projects in Asia and Africa. It provides information on the history and development of biogas projects in countries such as China, India, and Nepal. It describes different biogas plant designs including drum and dome designs. It also discusses inputs, outputs, and the various uses of biogas.
2. What is Anaerobic
Digestion (biogas)?
Cow is
anaerobic
digester:
gut has
population of
organisms:
break down
food for energy
Biogas plant: contains slurry at 35°C,
no oxygen, contain slurry, gas tight
3. Two scales of biogas
Large-scale systems
Industrial processing
Tank volume:
10,000 m3 and
above
Feed material:
500 tonnes a
day and
upwards
4. Two scales of biogas
Small-scale systems - Asia
Domestic processing
Tank volume:
1 to 10 m3
Feed material:
2 to 60 kg a
day
5. Inputs to a biogas plant
Cattle dung
seen as good
feedstock:
correct
organisms;
food chewed
so accessible
to organisms
Other animal dung: pig, horse, chicken
Human sewage
6. Inputs to a biogas plant
Food processing residues
e.g. market wastes
Vegetable matter
gives more gas
per kg, than dung
(animals & humans
already used energy)
Used to clean
waste waters
e.g. from coffee or
sugar production.
7. Inputs to a biogas plant
Energy Crops
Grown especially for energy production
Wastes can be
mixed: e.g.
Dung + sewage
Food residues +
sewage
All can be used at
any scale:
Domestic to
Industrial
8. Outputs from a biogas plant
Biogas: 60% methane 40% carbon
dioxide: high grade fuel
Used for cooking
Replace firewood
and charcoal, so
reduces
deforestation.
Replace LPG and
kerosene, so
saves fossil
carbon
9. Outputs from a biogas plant
Biogas: used as an engine fuel
Static engines to generate electricity
Need large
amounts of feed
material
1 tonne/day = 1 kW
Compress gas -
use in vehicles
Need 50% energy
in gas to do so.
10. Outputs from a biogas plant
Compost - value as an organic
fertilizer
Can be used as
liquid or dried
Better to absorb
in dry biomass
(straw) and then
leave to compost
11. Outputs from a biogas plant
Compost –add vermi-compost to get
very high value fertilizer
Gives 30% greater
crop yields
Worth £30 a tonne
cash-in-hand
Reduces pests and
diseases
12. History of biogas
Marsh gas used in C10 BC
to heat bath water (Assyria)
to make salt from sea water (China)
First biogas system in India –
Leper colony in Mumbai 1859
“Monster Septic Tank” gave gas for
street lights in Exeter 1895.
Used in sewage systems in Europe
from 1930s.
13. History of biogas
China
1920: Rural biogas systems developed
1958: National programme started
1978: 7 million plants built, but only
3 million working
Part of Chairman Mao’s “Great Leap
Forward”
Emphasis on rural self-support,
Built by local people
But lacking in quality control
14. History of biogas
China
1979: Chengdu Biogas Centre offers
quality control
New emphasis on training, follow-up and
monitoring
Individual family plants, use pig dung,
human sewage and food wastes
Sanitation + gas + compost
2009: About 17 million biogas plants
(< 50% success)
15. History of biogas
China
Mainly use underground masonry plants
of size 4 to 10 m3
Often use a concrete plug in the top of
the dome for easy access.
Some systems use the approach of
removing the slurry every 6 or 12
months as fertilizer and start again.
16. History of biogas
India
1897: Mumbai system gas used in lights
1907: gas used in an engine
1951: KVIC national programme
Developed floating drum design
Plants for individual farmers of volume
7 to 35 m3 with cattle dung as feed stock
Centrally planned programme with
government targets
17. History of biogas
India
1961: PRAD (state sector) involved
Adapted Chinese dome design as
“Janata” plant (4 to 10 m3)
1981: AFPRO (NGO sector) involved
Adapted Chinese dome design as
Deenbhandu plant (2 to 8 m3)
1981: DNES (government) gives subsidy.
2009: 12 million plant built
>60% success rate
18. History of biogas
India
2005 ARTI won Ashden Award for a
floating drum design made from HDPE
water tanks
Designed for urban families of volume
1 to 2 m3 with food wastes as feed stock
2007 Biotech won Ashden Award for
similar system, made from glass
reinforced plastics.
Domestic, Institutional and Market scale
19. History of biogas
Nepal
1955: Demonstration plant in school
1968: Indian (KVIC) plant at exhibition
1975: Government programme involved
Development and Consulting Services
(aid programme) and Agricultural
Development Bank of Nepal.
1976: Gobar Gas Company set up to
continue programme as commercial
operation.
20. History of biogas
Nepal
Pilot programme of 95 plants used KVIC
design with metal gas drums.
USAID funded R&D project developed
fixed dome design: cast-in-place
Cattle dung used as feed stock for small
farmers, using 4 to 20 m3 systems
Community plants tried, but social
problems prevented success.
21. History of biogas
Nepal
1986: Transferred to local management
with UNDP funding and Dutch (SNV) help
1995: BSP started: central co-ordination,
using many contractors (now 76)
SNV and GTZ provided subsidy
2009: 189,122 plants built
98% success rate
CDM mechanism gives subsidy
2006: won Ashden Award
22. History of biogas
Africa
Rwanda: Kigali Institute of Science and
Technology built sewage systems for
overcrowded prisons (10,000 people)
Underground masonry plants: 100 m3
volume, linked to make 1,400 m3.
Saves 50% of wood for cooking.
Funding from Red Cross
2006: Ashden Award
23. History of biogas
Africa
Biogas Technology West Africa Ltd.
building sewage systems for hospitals,
schools, colleges, etc.
Underground masonry dome systems
60 to 160 m3 volume.
Water recovered and used to flush
toilets.
Gas used for cooking.
24. Biogas Technologies
Drum
Floating drum
plant (KVIC
design)
Easy to see gas
amount
Drum can be
removed and
repaired
25. Biogas Technologies
Drum
Steel drum expensive
Needs to be transported to site
Needs to be
painted
Can be
removed if
loan not
repaid
26. Biogas Technologies
Drum
Several biogas projects in East Africa
have used KVIC design
BUT
Steel drum can
rust
27. Biogas Technologies
Dome
DCS design as used in Nepal, similar
to Janata design (PRAD) in India
Uses cast-in-
place concrete
dome
Lower cost,
but high
labour
requirement
28. Biogas Technologies
Dome
Uses displacement of slurry into
reservoir to collect gas
Concrete dome needs to be sealed to
make it gas tight
Long life
time, if
made
correctly
29. Biogas Technologies
Dome
Deenbhandu design made of bricks
High labour requirement
Uses
displacement
principle
Long life time,
if made
correctly
30. Biogas Technologies
Dome
Brick dome used for 100 m3 plants
Linked up to give 1,400 m3 plant
KIST project
for prisons in
Rwanda.
BTWAL for
hospitals,
school etc. in
Ghana.
31. Biogas Technologies
Dome
Construction approach simple
Needs highly skilled masons
Spherical
shape gives
high strength
Need weight
of soil to keep
dome under
compression.
32. Kingdom Bioenergy
Proposed Design
Prototype built in 1983 in Nepal
Uses an underground concrete system
Used in
agricultural
college.
8 more built in
2007 for large
agricultural
operations in
Nepal
33. Digester used with
pre-digester
Bioplex system (www.bioplexltd.com)
Trailer mounted – reduces handling
Fixed mounting also possible
57°C fast hydrolysis meets PAS110 for compost
34. Advantages of Kingdom
Bioenergy digester
Flexible system: can be made in a
range of sizes to suit farm operation;
Low cost: based on underground Asian
designs;
35. Advantages of Kingdom
Bioenergy digester
Adapted to UK:
pre-cast concrete sections; quick to build
well insulated
Use farming or food residues or both
36. Income/saving streams
from AD
Gas
Generate electricity (ROCs)
On farm for heat (replace LPG)
Compost (smell free)
On farm to replace inorganic fertilizer
For sale as compost (PAS 110)
Gate fees for food waste
New opportunities for biogas in UK and
across the world
37. Questions?
www.kingdombio.com
Book: Running a Biogas Programme: A Handbook
Practical Action Publishers (1988)
Updated version being written
www.ashdenawards.org